Ultralong Carbon Nanotube Yarns Integrated as Electronic Functional Elements in Smart Textiles

Ultralong Carbon Nanotube Yarns Integrated as Electronic Functional Elements in Smart Textiles

Smart textiles are an evolving field, but challenges in durability, washing, interfacing, and sustainability persist. Widespread adoption requires robust, lightweight, fully integrated fiber-based conductors. This paper proposes using ultralong carbon nanotube (UCNT) yarns with a width-to-length rat...

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Bibliographic Details
Main Authors: Ayelet Karmon, Ori Topaz, Raman Tandon, Andy Weck, Ortal Tiurin, Sheizaf Rafaeli, Zeev Weissman
Format: Article
Language:English
Published: MDPI AG 2025-04-01
Series:Textiles
Subjects:
smart textiles
e-textiles
weaving
nanofibers
carbon nanotubes
Online Access:https://www.mdpi.com/2673-7248/5/2/13
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Summary:Smart textiles are an evolving field, but challenges in durability, washing, interfacing, and sustainability persist. Widespread adoption requires robust, lightweight, fully integrated fiber-based conductors. This paper proposes using ultralong carbon nanotube (UCNT) yarns with a width-to-length ratio of several orders of magnitude larger than typical carbon nanotube fibers. These yarns enable the manufacturing of stable, workable structures, composed of a network of twisted fibers (tows), which are suitable for fabric integration. Our research includes the creation of textile prototype demonstrators integrated with coated and non-coated UCNT yarns, tested under military-grade standards for both mechanical durability and electric functionality. The demonstrators were evaluated for their electrical and mechanical properties under washability, abrasion, and weathering. Notably, polymer-coated UCNT yarns demonstrated improved mechanical durability and electrical performance, showing promising results. However, washing tests revealed the presence of UCNT nanofibers in the residue, raising concerns due to their classification as hazards by the World Health Organization. This paper examines the sources of fiber release and discusses necessary improvements to coating formulations and testing protocols to mitigate fiber loss and enhance their practical viability. These findings underscore both the potential and limitations of UCNT yarns in military textile applications.
ISSN:2673-7248

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